Scale



G. R. WOOD SCALE Original Filed July 19. 1.919 8 Sheets-Sheet 1 March 29, 1927.

March 29 G. R. WOOD SCALE Original Filed July 19. 1919 8 Sheets-Sheet 2 W l f toimqy March 29 1927.

G. R. WOOD SCALE 8 Sheets-Sheet 5 Original Filed July '19. 1919 lllmmlll March 29, 1 92?,

G. R. \I'VQOD SCALE 8 Sheecs-Sheet 4 n l Filed July 19, 1919 March 29 1927' R. WOOD S GALE Original Filed July 19, 1919 8 Sheets-Sheet 5 MGM wwm m Owm mmm BMW mm? mum mmm R. NOQD SCALE Marcia 29s 1927,

Original Filed J ly 19. 1919 8 Sheets-Sheet 6 March 29, 1927.

G. R. WOOD SCALE Original Fil d J l 19. 1919 8 Sheets-Sheet 7 March 29 1927.,

G. R. WOOD SCALE Original Filed J l 19, 1919 8 Sheets-Sheet 8 Patented Mar. 29, 1927,

UNITED STATES PATENT OFFICE.

GEORGE R. WOOD, DAYTON, OHIO, ASSIGNOB TO DAYTON SCALE COMPANY, OF DAYTON, OHIO, A COBPOBATION OF NEW JERSEY;

SCALE.

ori inal application filed m 19, 1919, Serial No. 912,099, and in Canada July is, 1919. Divided and um application filed larch 4, 1924. Serial No. 696,784.

This invention relates to improvements in Weighing machines and more particularly to machines which are adapted to record the weight. Certain features of the invention are directed to a combined computing mechanism which is adapted to multiply the weight of the goods by an amount such as price per unit of weight and display or otherwise designate the. resulting product.

Provision is made for recording the product.

Further objects of the present invention are directed to the provision of certain novel connections intermediate the weighing and recording mechanism or intermediate the weighing and computing mechanism in order that the latter mechanism may be set in accordance with the setting of the weighing mechanism. v

Further objects of thepresent invention reside in the provision of a novel form of controlling connection of such character as to avoid strains upon the weighing mechanism and to permitfihe removal of applied loads directly after a computing or recording operation is initiated.

This application is a division of my copending application, Serial No. 312,096, filed July 19,1919.

For full comprehension, however, of my invention, reference must be had to the accompanying drawings in which similar reference characters indicate the same parts, and wherein:

Figure 1 is an elevation of the side of the machine towards the customer with the case removed;

Figure 2 is a similarpview of the left end of the machine as'viewed in F i re 1.

Figure 3 is an elevation of the side of the machine towards the merchant;

Figures 4, 5, 6, 7, 8, 9, 10, 1'1 and 12 are details of the controlling mechanism for determining the 'extent 'of movement of the computing wheels;

Fig. 13 is a detail sectional view taken on line A--A=of F ig'.'1 and looking in the direction of the arrows. This figure particularly illustrates the starting mechanism.

Fig. 14 is a frontelevational view taken fromthe left of Fig. 13 and looking to the ri ht. r

Fig. 15-- is a horizontal sectional view of the starting mechanism taken on litrefBB of Fig. 13.-

Figures 16, 17,18 and 19 are detail illustrations of a locking means forming part of the starting mechanism;

Figure 20 is a detail view of a releasing hammer forming a part of the starting mechanism;

Fig. 21 is a detail sectional view illustrating aportion of the rate mechanism, the section being taken substantially on line C() of Fig. 1.

Figure 22 is a transverse sectional view of the machine taken on line I)D of Fig. l and illustrating the rate mechanism and more particularly the rate wheels, their operating and locking instrumentalities and the rockers and other coacting parts;

Figures 23 and 24 illustrate in detail parts of the computing wheels;

Figure 25 is a transverse sectional view ofthe frame taken on line E-E of Fig. 1 illustrating the printing mechanism partly in elevation and partly in sectional view;

Figure 26 is a detail view of the mechanism at one end of the machine and including parts of the computing and printing mechanisms;

Fig. 27 is a detail view taken substantially on line FF of Fig. 1 illustrating the cam and coacting levers of the computing and printing mechanisms.

Figure 28 is a detail view illustrating the mechanism of Figure 27 in plan view;

.Figure 29 is a transverse sectional view on line G-G of Fig. 3 of the upper part of the machine and illustrating particularly the mechanism for the purpose of indicating to each purchaser the result of the computation in which he is concerned;

1 Figure 30 is a detail view of one of the indicator wheels;

Figures 31 and 32 are a detail side elevation and sectional view, respectively, of one of the indicator wheels; Figure 33is an axial sectional view, and Figure 34 isa side elevation on line H-H of Fig. 1, of a portion of the weight and price computing mechanism and parts of the means for causing the weight wheel and price computing wheels to rotate to com-v outin ition'. t l. a P 7 the'r detailsof the weight and price computing mechanism-;

Figu're39 is a transverse sectional view of Figures '35, 36, 37 and illustrate fur-- the machine talten on line J-J, Fig.3, and showing the computing mechanism and illustrating particularly the mechanism by which the indicating. wheels are rotated;

Figures40, 41 and 42 are, respectively, a

longitudinal axial sectional view through well adaptable to other kinds of computing machines of this type.

The machine frame comprises upright end sections 2 and -3 and intermediate sections 4 and 5, the sections being connected together by horizontal bars and spacing ferrules' 7. The outside casingrand the platform of the :scale are not illustrated as they may be of any desired construction. The various mechanisms are actuated by a cam shaft 8 which is journaled in sections 2, 4 and 5 of the machine frame.

TUontrolling' mechanism.

In the embodiment of my invention herein illustrated I have shown my invention applied to a computing scale in vwhich one of factors of the computation is based upon weight and the other factor is the price per pound of the commodity weighed. The :11) paratus is also adaptable for other computmg pur ose's.

In weighing apparatus particularly, it is desirable that the weight setflmember be not positively locked. Otherwise excessive strains may e set up on the mechanism if weight is removed or added to the platform after the weight set parts are locked. Also the computation-will be performed with an incorrect weight and an incorrect result will bev secured. In order to minimize these d1fficulties I have provided two elements both of which are set in proportion to weight.

Intermediate these" elements is a yielding connection and locking means is provided to cooperate with -one of the elements. The

other element is therefore free to move 'under the influence -.of a change "of weight and this element is so located as to disclose the movement thereof to the operator and the customer. A part of this mechanism, namely, the locked'eleme'nt or wheel .is used as a controlling mechanism for thejcomputationi to be performed. This mechanism will now,

be described. The element to be locked comprises a comparatively light .wZheel having-a rim 12 (Figs-land 6) and'provided with spokes 27 Fig. 8). radiating froma suitable hubjltl which .i'slrigidly carried by shaft 14;.

This-shaft is freeito rotate inthe machine frame, and has. its reducedends 15 journalled in ball-bearings 16, one of the bearings being carriedby the endframe 3 and the-other by a vertical standard 17. Each of these bearings consists of a runway .18 in the form of an'external screw-threaded disc containing anti-friction balls 19 and locking screws 20 and 21.]The .external screwthreads .on the runway 18 permit of axial.

scribed. For compliting quantities other than those to whic the embodiment illustrated is adapted, this wheel 509 may be 0perated in any desired manner whereby it willhave an extent of movement determined by the quantity computed. Inthe embodiment illustrated it is operatively connected to the platform of the scale by a pinion 22 rigidly mounted upon an axial extension. of the hub 510. and it is in intermeshing relation with the teeth ofa rack 23, such rack being operativel connected to the platform in any preferre manner to exert a downward pull upon the rack when-an article is thrown upon the scale. This downward pull causes the wheels 509 and 12 to rotate until the-graduation of weight representing the weight} of the article upon the scale comes opposite an a erture in-the side of the casing towards .t emerchant. At this. point the wheel is adapted to be locked against further rotation. To this end a toothed annulus 28 is mounted rigidly on the wheel 12 and its diameter equals that of the wheel. A locking pawl 29 is adapted to be moved into engagement with the teeth of this annulus by means to be hereinafter described, the awl being constitutedby the downwardly bent free end of an overhanging arm 30 theopposite end of which rigidly carried bya shaft 31.

- As the controllingnnechanism is of a very light construction it is necessary to provide means for reducing to a minimum the stress and strain exerted thereon when, for instance, a comparatively 'heavy weight is either removed from or added to the weight uponthe platform while the toothed annulus is in locked position. Furthermore, it. may be found desirable to. commence a succeeding computing operation-, before the initial-open anon hasheen completed." To" this end an intermediate" connection between 5 wheels 12 1 and 509 is provided which'will per'mit'rotation qf the latte while the former is locked. This connection' is effected by air-intermediate flan ed hub132 mounted rotatably upon the shaft 14 between-the hubs 10 and 510.

This hub. is providedwith arms 34- and' 35 extending from opposite sides thereof at tit) right angles to the shaft 14, such hub being free to revolve on the shaft and its arms are adapted to be engaged by stops 36 and 37 carried by the respective wheels 12 and 509. A spiral spring 38 is connected at one end to the hub 32 and at its other end to a pin 511 on wheel 509. A second spiral spring 39 is connected at one end to hub 10 and at its opposite end to a pin 512 on arm 34. The purpose of the springs is to automatically take care of rotation of the wheel 509 in either direction while the annulus 28 is locked thus serving as a shock absorber and permitting the commencement of a succeeding operation before initial operation has been completed. If, :t'or instance, a five pound weight is placed upon the scale while a computing operation is taking place a downward thrust of five pounds will be exerted upon the pinion 22 by the rack 23 and this thrust will be taken up by the spring 39 as the stop 37 will engage the pin and rotate. it in a clockwise direction looking from the adjacent end of the machine frame, this action obviously winding up the spring. If, 'in another instance, the locking pawl is in locking position and a weight is taken off the platform of the scale; the upward push of the rack 23 will rotate wheel 509 and wind up spring 38 as stop 36 prevents rotation of the hub 32.

When the wheel 12 has come to weight-indicating position and the starting key depressed the pawl 29 is adapted to move automatically into contact with the teeth of the annulus 28 and lock the same against further rotation. This actuation of the pawl is eiiected by a cam 40 (Fig. 5) rigidly mounted upon the shaft 8 and having an abrupt drop 41 and a rise 42, the remainder of the cam being of uniform diameter. Bearing against the perimeter of this cam is a roller 43 rotatably mounted upon the free end of an arm 44, the opposite end of which is rigidl secured toa shaft 45 journalled in the machine frame near the bottom thereof and which also rigidly carries a second arm 46 extending parallel to the first mentioned arm and having its free end connected to the lower end of a pull rod 47 The upper end of thispull rod is pivotally connected to the free end-of an arm 48 extending parallel to the arm 30 and rigidly carried by the shaft 31 located near the top of the machine frame. A helical spring-'49 having its opposite ends connected respectively to the ma-- chine frame and the free end of arm 46 normally maintains the roller 43 in hearing relation with the periphery of the cam 40 and the pawl 29 out of engagement with its toothed annulus.

As the extent of movement of the pawl 29 relatively to the toothed annulus is limited, it is necessary to provide resilient means in the cam shaft.

the operative connection between it and its actuating camto take up any surplus throw of the latter. To this end the pull rod is constructed in two parts, the upper part having ayoke 50 rigidl connected thereto, the lower part of the pn 1 rod extending upwardly through the yoke and being connected to a sleeve 51, the upper end of which slidably receives the lower end of the upper part. A helical spring 53 encircling the lower part of the pull rod and bearing between the sleeve and the lower end of the yoke is adapted to maintain the parts in their normal relative positions.

When the pawl 29 is out of locking position the roller 43 is located within the drop 41 on the cam but almost immediately the cam commences rotation the roller moves up incline 42 thereby pulling the pawl into engagement with the teeth of the annulus and the pawl is held in this position for approximatelv one revolution of the cam.

Be ore describing in detail the various computing mechanisms 1 shall explain the starting mechanism for setting the computing mechanisms in motion.

Starting q'rzeclzaniam.

The starting power is preferably derived from a motor 54 (Fig. 1) which is mounted upon a bracket 55 rigidly secured to the end 3 of the machine frame. it is to be understood, however, that a crank arm or other manually operated means may be employed for setting the machine in motion without departing from the spirit of the invention. The motor drives a shaft dividedinto two parts, a rigid part 56 and a laterally movable part 57, the parts being connected by a universal joint 58. Rigidly mounted upon the inner end of the part 57 relatively to the machine frame is a gear 59 adapted to intermesh with a gear 60 rigidly mounted upon In order to simultaneously move the gears 59 and 60 into intermeshing relation when the switch 61 of the motor is closed, one end of a carrying arm 62 (Figs. 13-18) is rigidly mounted on the adjacent end of a shaft 63 extending across the front of the machine frame. This carrying arm is provided with an enlargement approximately midway in length containing a substantially vertical slot 64. One end of a lever 65 is pivotally mounted on this arm and has a circular hole 66 adapted to register with the slot 64. This hole 66 constitutes a bearing for the reduced end 6? of the adjacent shaft part 57, such reduced end projecting into the slot 64 and thereby allowing a limited relative movementbetween the carrying arm and the lever (35. The object of this arrangement is to prevent mutilation of the gears when the switch is closed and the former are not in proper intel-meshing relation. A spring 67 (Figs. 13

and 19) having its ends connected respectively to the lever 65 and a downwardly projecting arm 68 formed integrally with the carrying arm 62 is adapted to resist relative separation of the carrying arm and the lever while a lug 69 on the lever limits movement of the latter relatively to the arm. The free end of lever 65 is correspondingly cut away as at 700 for engagement with a pawl 701 pivoted at its lower end upon the back of the main pawl 83, the latter being cut away as 702 to accommodate the same. A spring 763 mounted on the main pawl yieldingly resists relative separation of the pawls.

When the switch is closed it the gears 59 and 60 are in proper intermeshing positions, the two pawls will lock arm 62 and lever 65 simultaneously, but if not in proper intermeshing positions the auxiliary pawl will not act until such gears are moved into relative inter-meshing relation. The arm 62 at a point adjacent to its free end carries the blade of the switch 61, the latter being rigidly mounted on an angular bracket 71 rigidly secured to the machine frame. The terminals of this switch are included in an electric circuit 72 which also includes the terminals 73 of the rheostat and-the terminals 7-3: of the motor, the latter being can I ried by a block 75 secured to the machine frame near the top thereof. The switch is closed and the gears moved into intermeshingrelation with each other by a manually operated starting key 76, one arm of a bell crank lever pivotally mounted in a bracket 7 7 on a horizontal face plate 78 extending across the front of the machine frame, such plate having a plurality of vertical slots 79 through one of which the key 76 projects. The other arm of the bell crank lever is operatively' connected to the forked upper end of .an arm 80 which is rigidly mounted upon the shaft 63 in close proximity to the section 4 of the machine frame so that when the key is depressed such shaft is rotated and the carrier arm 62 with gear 59 and blade 70 is swung down until the are in their operative positions. A ten ency oi the arm 62 to move upwardly is imparted to itlby a spring 84 which is connected to it and to an adjacent part of the machine frame. Rearward movement of'the pawls 83 and 701 is limited by a rigid pin 112 project-.

ing from the machine frame. In order to automatically release the arm 62 and lever 65, after the various computing mechanisms haveperformed their respective functions and the com'putationshave been completed,.

means is provided for moving the pawl's83 and 701 out of engagement with arm 62 and lever 65. To this end the pawls are carried by a shaft 85, such shaft also having a messes" 87, such hammer in close proximity to the end of its handle being pivotally connected to the middle of an arm 88 carried by a shaft 89. This shaft also has a second arm '90 rigidly mounted upon it and in bearing relation with the perimeter of cam 91 mounted on the shaft 8, such cam having a drop 92 which is timed to cause the hammer to engage the. arm 86 when the switch is to be opened. A spring 93 maintains the pawls in proper operative relation to the free ends ot the arm 62 and lever (35 while a second spring 24 connectin the arm 88 to the machine frame maintains the arm in bearing relation with its cam. It will be noted that the hammer 87 is only in contact with the arm 86 when striking, the pivotal connection of it to the arm 88 permitting it to swing up by its own impetus into engagementwith the arm 86. This prevents any interference with the locking action of the lever 83.-

After the wheel 12 is positioned and looked a stop pin 95 (Fig. 6) carried by the annulus 28'which is fixed to the wheel is utilized to limit the movement of'a certain series of parts which may be called diiferential controlling devices. These differential controlling devices are moved by an independent source of power to a position to be limited by the aforesaid pin. When the parts cooperate with the pin they contact therewith so lightly and in such a manner as not to tend to displace the locked wheel from its previously set position. Furthermore, the differential controlling devices Which in turn control the extent of movement of certain of the computing devices are in themselves locked upon cooperation with the limiting pin whereby the position of the parts is definitely determined and possible overthrow thereof is prevented.

Power to drive the difierential controlling devices is derived from a spring 190' (see Fig. 33) to be hereafter described. This spring power tends to rotate shaft 99 and rotation of this shaft commences as soon as a cam 216 moves away from afollower 215 (see Fig. 34). The follower and cam is ar-.

ranged to restore power in the s ring at the roper time in the cycle of t e machine. hese features will be hereafter described. The difierential controlling devices are shown in Figsxfi, 7, 9'end 10. In Figs. 7 and 9 theshaft 99 is the shaft which: is impelled to rotate in a clockwise direction by the spring previously mentioned. Fixed to carried by 108. Pivoted upon a stud carried by arm 98 is a lever-101 and the free end of this lever is extended at right angles to its length at 102 and carries a laterally extending stop 96 in the form of a pin. Carried by the end of arm 98 is apivoted pawl 100. This pawl is of substantially L form, the toe portion overlying a toothed annulus 97 which is fixed to the frame of the ma chine (see Fig. 6). The shank of this pawl is extended to form a tail 105 which lies in the path of the end-of lever 106. The pawl 100 is normally maintained out of engagement with the toothed annulus by means of a link 103 which connects, the pawl .with the portion 102 of lever 101.- Lever 101 is normally urged forward relatively to carry- 1 ing arm 98 by a blade spring 715 thereby holding the pawl out of engagement with the annulus 97. The distance which the pawl is held out of engagement is determined by an adjusting screw 716 which is carried by the arm 98 and 'extendsin the path of lever 101.

The operatlon of the differential controlling devices is as follows. The energy of the spring 190 which may be termed a motor spring reacts to impart clockwise rotation to shaft 99. Lever 106 is concurrently rotated clockwise andarm 98, parts 101, 102 and 96 swing in unison with the. lever 106: Arm 98 is-in advance of lever 106 (see Fig. 10). The advance is caused by the tension of spring 109 and the amount thereof is limited by stop 110. Arm-101 is also in advance of arm 98 and in contact with stop 716. The path of pin 96 coincides with the path of pin and upon contact therewith parts 102, 101 will be displaced rearwardly relative to arm 98- thereby rocking pawl 100, into engagement with fixed annulus 97 and stop ing further forward movement of arm 98 see Fig. '9); Lever 106 continues to rotate extending spring 109. This supplementary rotation of lever 106 swings the end of the same under the tail 105 of pawllOO (see Fig. 7 thereby lockirfg the pawl into engagement with the toothed annulus and preventing any rebounding after being swung into engagement therewith. The part 106 is now arrested. The computing member or members whichrotate in unison with the shaft are also arrested and these parts are so timed as to take into account i the slight angular travel which occurs between the initial engaging of pawl 100 and the final arrest of arm 106.

Weight and price computing mechanism.

1 The members proper for computing weight and price consist of a plurality of wheels. In the 'embodimentillustrated there is one weight wheel 113 and nineteen price wheels 114. In machines of thistype it is most important that friction be reduced to a minimum in order that comparatively light parts may be employed and that accurate computations be secured. To this end I have mounted the wheels upon a floating axle. This axle is carried by the shaft 99 (see Fig. 33) and consists of a sleeve 115 the opposite ends of which roject into cup-like bearings 116 and 11 respectively, the bearing 116 being constituted by the hub of the weight computing wheel provided with a chamber 118 into which theadjacent end of the sleeve projects and between the walls of which and a circumferential concavity 119 on the sleeve are antifriction balls 120. The hub 116 is provided with an axial projection 121 of smaller diameter which projects into a bearin of cup-like form 122 rigidly secured to t e adjacent section 4 of the machine and containing antifriction balls 123. The extension of the hub is keyed to the shaft as at 124:. Thebearing 117 at the other end of the sleeve is of similar construction and consists of cup-like member 125.rigidly mounted in a drum 191 and con taining antifriction balls 126. bearing between it and the adjacent end of the sleeve,, the drum 191- being keyed to the shaft 99 as at 127. The drum 191 is provided with an axial extension 128 of comparatively small diameter upon which is rigidly mounted a gear 129 and anarm 130. This axial exten sion 128 is located adjacent to section 5 of I the machine frame havin large opening 131 throng which the shaft projects. On the opposite side of the section 5 is rigidly fastened another cup-like member 132 the inner wall of which is screwthreaded as at 133 to receive an adjusting disc 134,. one side of which constitutes one side of a runway for antifriction balls 135 bearing between it and a circumferential flange 136.formed integrally with a collar 137 rigidly keyed tothe shaft 99 vas at 138. The disc 134 makes possible the adjustmentof the various bearings as through it the shaftr99 may be shifted axially.

With the exception of the weight compnting wheel all of the wheels present three computing circumferences, each circumference corresponding to. a denominational order; the weightwheel, however, presents four. This latter wheel consists of two spaced discs 150 and 151 rigidly secured to opposite sides of the hub 116, these discs in turn rigidly. carrying two intermediate rings 152 and 153 and the circumference of a comparatively both discs and rings are notched throughout the depths of the" notches being in proportion to each other, a predetermined depth, representing so many. units. ofvalue. The depths of thenotches in the disc 151 repre sentunitsof; ounces'and those of 152 and .-1'53=and disc 150, tens-of ounces, units of pounds and tens of pounds, respectively.

The rings and discs are spaced apart by. v

- lower half of each of the borings 175 is ferrules 154.

The price computing wheels (Fig. 23) are of the same diameter as the weight wheel and each consists of a hub 155 having a circumferential flange 156 upon which is rigidly mounted adisc 157. This disc rigidly carries two rings 158 and 159 spaced apart bythimbles 160 and the circumferences of the three, are notched in a similar manner to the .weight wheel. The hub 155 is adapted to rotate on the floating axle 115.

For a proper understanding of the mechanism now to be described the cycle of operation of the computing and weight wheels must behere described. The amounts are taken off from the wheels by afseries of pins. There area" group of-pins for each computing wheel and a group for the weight wheel. Each pin group comprises a plurality of pins, there bein one pin for each denominational order.

the scale and with the computing wheels and weight wheel in normal homeposition all the roups ofpins would align with deep notc es 161' in these wheels and the pins could all be depressed without being arrested by contact with the wheels. In the normal operation of the machine all the computing v whee1s are first at-home position and are -all locked in this position. The depression of a rate key selects and unlocks a particular computing wheel. Thereafter upon movement of the differential controlli this previously selected wheel is i ocked to a part which operates in unison with the difi'erential controlling device. Theselected computing wheel and the weight wheel which always operate in unison with any selectedrate wheel are displaced angularl in accordance with the movement of the di ferential device. The pins are then depressed and areading istakenfrom the 1 selected computing wheel and the weight wheels.) in unison with the group of pins which are being-arrested by the selected computing wheel and rate wheel but these pin grou s are inefi'ective as they pass idly down in'the notches 161' previous mentioned.

A guide bar 170 o rectangular cross-sec- 'tion' (Figs. 39,37 and 22)-is carried by the machine frame in the vertical axial plane of the computing wheels; and immediately above the same, the ends of the bar being seated in brackets 171 and 172, the end rest inginthe former bracket being remoyablef and held in position by a pin 173. This bar is divided vertically and longitudinally into two parts and is I sage therethrough of in's -174. havingt eir extreme lower ends o increasedwidth and constructed and arranged to cooperate with ll groups of pins operate in unison and with no load upon,

devices.

The other pin groups are depressed bored topermit of the as the notched peripheries of the computing wheels in effecting the computations. The

In order to align all of the computingwheels in one position when idle, each wheel,

is provided with a radial projection 177 one radialed e of which isadapted to bear, against t e guide bar 170, t e other edge I being engaged by a'bar 178 of substantially UY-form and straddling the seriessof collb .puting wheels. This bar yieldingly engages the projections 177 and aligns them. against the guide bar when the wheels are idle.

One arm 179 of this 'U-bar is v *pivotally mounted as at 180 upon the disc 150 of the weight computing wheel, the other-arm 181 being pivotally carried. by the arm 130,

hereinbefore mentioned. The free. end of the latter is provided with a laterally. projecting lug 183 adapted to engage the U-bar and prevent relative movement between it and the arm 130 in one direction; Relative movement in the opposite direction is resiliently resisted by a spring 186 having its ends, respectively connected to the U-bar and the free end of an arm 185 formed integrally with the arm 130. A spring-187 performing a similar function connects the other arm of the U-bar to the disc 150. The object in pivotally mounting the 'U-bar upon the the shaft 99"is to permit the lJ-bar to take care of any surplus rotation which may be imparted to the shaft 99 by the means for returnin the wheels to their initial ositions. his means is hereinafter described. The means for causing the weight wheel and the price computing wheel, the notches in which represent multiplies of the rate.

entering into the computation, to rotate to computing position, consists of a spiral clock spring 190 which is wound upon the drum 191 in a counterclockwise, direction looking towards the machine frame and con-- tained in a box 720. x The ends of this spring are respectively. connected to a hook on the drum 191 andto-the' circumference wall- Y of the box. The torque of the spring 190 is constantly exerted upon the drum 191 and the weight computing wheel and U-bar, but not on the price computing wheels as the latter are freely mounted. u n the floating putation. I

When thecomputing members have automatically returns thein to their initial formed their computing functions the U-bar axle 115 under the control o the U-bar, and a locking and releasing device constituting the price comp ting. w els' 'for each=com-' arm and disc instead of directly to positions. The means for causing this action of the U-bar consists of a rack in intermeshing relation with the gear 129 and extending therebetween and a roller 211 mounted on the adjacent portion of the machine frame. One end of this rack is pivotally mountedin the forked upper end of one arm of a bell crank lever 212 which in arm 214 downwardly, the rack being thereby shifted towards the rear of the machine frame. 2 position with the guide bar 170 until the The cam locks the U-bar in juxta-,

next computing operation, thereby holding the computing wheels in home position (see Fig. 35).

- Rate mechanism.

The rate computing mechanisms are in intimate cooperation with the weight and price com uting mechanisms as each controls a l ing device for the U-bar. There are a plurality of rate buttons 200 (Figs. 1

and 22), the shank of which extend-through slots .in the face plate 78. ,Theisebuttons are preferably arranged in two series, the

series being relatively staggered and each-- button is adapted to actuate a mechanism independently of the others, a series of is located immediately beneath its res ective arms 232. areoperativelyeonnected into an oscillatory movement of the rockers. When price computing wheel." This hOIlZOIltill arm 224 is of substantia'ly L form, the toe "of the L'being comparatively wide as at 225 and notched as at 226 to permit of varying extents of movement of preferably-three nested rockers 227, 228 and229, the rockers" extending horizontally beneath the arm;.224 audbeing'suspended by vertical arm's 230 from a'shaft231. An arm 232 is rigidly fastened to each of the arms 230 thus ob taining a bell crank action which converts the downward push of links 233 to which the each of the arms 224 is' not in computing positionv it. is located above the path of the rockers but when one of the rate buttons is pressed the arm is swung down until its toe intersects such path and causes the printing and indicating mechanisms. to be hereinafter described, to be actuated in proportion to the extent of movement of the rockers within the notches. The arm 224 is locked in its computing position by a locking bar 234 mounted upon the upper ends of three arms 235, 236 and 237, the latter being comparatively wide. These. arms are rigidly carried by a shaft 238. The locking bar extends throughout the series of rate comput ing arms 224, is common to all and is adapted to engage a shoulder 253 (see Fig. 22) constituted by a notch on the rear end of each of such arms. A spring 239 having its ends connected'to a bar. 240 and an ,arm 241 imparts to the locking bar a tendency to engage the shoulder 253 when one of the com-;

puting levers is actuated, the arm 241 extending at substantially right angles to the I arm 237 and being rigidly connected thereto while its free endcarries a .roller 242 constructed and arranged to bear upon the circumference of' a cam 243 of substantially uniform diameter. throughout and havmg a radial projection 244 constituting a short rise and fall, such projections dis: engaging'the rate lever from the bar 234 when the computation has been completed. A spring 245 having its ends connected to a bar 246 acrossthe back of'the machine frame and a cotter pin 247 causes-the lever 224 to return to its initial position out of the path .of the rockers when it is released. The cot ter pin 247 pivotally'connects the lower end of a pull rod 248,, to each of the rate computing levers and the upper end I of this pull rod is in turn forked and pivotal 1y connected to the tail 249 of a locking pawl 250 which is rotatably "mounted on a shaft 251, and adapted to lock the respective, price computing wheel of the rate lever to which it isconnected. It will be understood that there is one awl 250 for each computing whee.. Eaci pawl when in lockin position (i. e., full line osition in Fig. 22

swings down behind a liig 252 on its price computing wheel. This lug is turned in fromthe ripheizy of the wheel and is shown in ig. .24. With the parts in full line position as shown in Fig. 22 there is a double lock for the computing wheels. Lug

made of the third lock comprising pawl 250 and lug 252 to lock all of the wheels except the one which is to'be selectively operated in unisonwith the 'U bar. fwhilepreventing rotation of the computing wheel the .pawl also bears down upon an angular bent flange the side of the computing wheel as at 256 and having a tail 257. This pawl is constructed and. arranged to swing radially a sufiicient distance to intersect the path of the U bar .when the'pawl 250 is released, such radial movement being imparted to it by a spring 258 having its opposite ends connected respectively to the computing wheel and tail 257.

In the operation of this mechanism when one ofthe rate buttons is pushed in, pu.l isexerted upon the rod 248,-and the pawl 250 is swung out of engagement with the 'flange on the pawl 255 thereby permitting the latter to-intercept the U bar and simultaneously release the computing wheel upon which such pawl is mounted so that only the respective computing wheel of the rate mechanism actuated is rotated. The pawl 255 of the seected wheel swings up behind the U bar 178 and rigidly couples the wheel to the bar.. The selected wheel, it will be understood, rotates clockwise as viewed in Fig 22 and will be held to the U bar by the conjoint action of lug 177 and pawl 255 which 'engage the U bar atopposite sides thereof.

In order to provide means for returning the rate lever the button of which has been inadvertently pushed, a bell crank lever 260 (Fig. 21) of a contour similar to that of the rate levers is mounted upon the shaft 222 at the right of the series of rate levers and its substantially vertical arm is operativelfy connected to'a release button 261. The di ference between this release lever and the 1 other levers is that it is not notched and presents a convex edge 262 projecting rear-- wardly of the other levers whereby when the release button is pushed in such convex por- 'tion en'gagesthe locking, bar 234 and shifts it to the rear disengaging it from the shoulder 253 of the rate lever which 'has been inadvertently operated. An upward pull is exerted upon this rate lever by a spring 263 fastened to the bar 246. If, for instance, a certain rate button has been pushed in and the operator desires to change the rate, he may do so by pressing in the desired rate button as this action automatically displacesthe locking bar 234 from the rate lever of the rate mechanism first operated, the bar being displaced by the convex edge on the end 225 of'each rate lever. It is optional whetherthe operator changes therate by releasing the button'inadvertentl pressed through the release mechanism or t e desired rate mechanism, but if it is found that no computing operation is necessary after a button has been pushed in, only the release -mechanism would be emplo ed because if one rate button is released second in its turn will be 100 There is a combined means for movmg the g another the ing bell crank lever which has been operated.

This means also indirectly actuates the type printing mechanism. to be presently described, the extent of movement of the type being controlled by the computing pins and rockers respectively. This combined means consists of a sleeve 270 (Figs. 26 and 27) freely mounted upon a shaft 271 and carrying rigidly upon its opposite ends laterally projecting arms'272 and 273, the free end of arm 273 being in operative relation with a. Scam which will be hereinafter described. The free end of the other arm is pivotally connected." to an arm 274 by a substantially vertical link 275, the arm 274 being rigidly mounted upon one end of a shaft 276, which shaft has a correspondin arm. 277 on its opposite end. The pivota connection of the link 275 tothe arm 274 is located substantially midway the length of the latter as at- 279 and the free end of such arm and arm 277 are in turn pivotally connected to a. vertical reciprocatory yoke 280 of inverted U form." .The horizontal portion of this yoke has a plurality of holes bored therein to permit the free passage therethrough of four groups of pull rods 281, 282, 283 and 284. The lower ends of these rods are of increased diameter to present enlargements 285 to prevent the displacement of springs 286 encircling the pull rods and bearing between'such enlargements and the underside of the yoke, the upper SldQ Of the latter bearing against collars 287 rigidly carried by the pull rods. The upper ends of the pull rods are operativel connected to the arms 290 rigidly carried by two vertically aligned and spaced series of 'rock shafts 291, the arms carried by each series extending towards the other series and the oscillatory action exerted u on these shafts by downwardmovement o the pull rods 281 istransferred to the push rods 233 and the computing pins 174 by arms 292- pivotally connected to the same (see Figs.

larly used for weight, there being one shaft.

for each denominational .=order thereof or two for pounds andtwo for ounces. For

the product or price three shafts are utilized, there being a separate rock shaft for each,

denominational order thereof. The push rods 233, as hereinbefore stated, are con nected to the-rate computing rockers 227, 228 and 229. y The lower ends of the pull rods 281 are connected to the type sectors constituting the printing mechanism. the

pounds sectors being indicated by 293, thecarried by the right handrate sector which also prints the fraction when the rate includes one, such type sector havinga lug 299 (Fig. 26) formed integrally thereon to carry the cent sign opposite the fraction. These fixed type are held in fixed position by a bar 300, the ends of which are mounted in. upright sections 2 and 4 of the machine frame and extendingthrough holes in upward extensions 301. f' "Downward pull ex-. erted upon the link 275 moves the yoke 280 in the same direction and the movement, con tinues, swinging with it the various movable type sectors 293, 294, etc., until the "computirig pins 174 and computing rockers reach the bottoms of their respective notches, at which point further movement of the type sector is prevented, the springs 286 taking up the continued movement of the yoke, the downward stroke of which is the same extent of each computation. From this arrangement it will be seen that the type sectors will assume different relative positions according to the depths of the notch in the respective computing members.

The means for causing thisrdownward movement is a pair of cams combined to function as one and hereinbefore alluded to as being in operative relation with the arm 273. This combination consists of a single leadei'cam 302 and a double leader cam 303, both rigidly carried by the shaft 8 and adapted to coact in unison withv each other.

,The arm 273 carries a roller 304 which is adapted to bear upon the periphery of the double leader cam 303, and an assisting lever 305 having one end pivotally mounted on the arm 273, as at 306,carries a roller 307 adapted'to bear upon the periphery of the cam 302, the free end of the lever being re- 'siliently connected to a bar 308 by a comparatively heavy helical spring 309. The purpose of the spring is to maintain the roller 307 in bearing relation with its'cam and to assist in effecting the downward pull upon the pull rods by exerting tension upon the arm 273 through the medium'of a lug 310 carried by the arm 305. The single leader cam is provided with an abrupt fall 312 and the doubleleader earn a more gradual one, 313, and the former is timed to occur immediately in advance of the latter in order that the full tensionpof the spring 309" maybeexerted upon the arm 273 when it commences its downward swing. The commencement Of'thlS downward movement signals the computing stroke of the pins and lever to a'transverse wire 3 44;connec ted *the hammer arms. A hmitlng tail 350-ex-v rockers respectively. When the roller 304 reaches the lower end of the fall 313 the computing stroke has been completed and such roller then rides along a portion 314 of substantially uniform radius during which time the-printing mechanism comes into action. A rise 315 on the single leader cam is also in advance of the rise 314 on the double leader cam and is-o'f "a contour to effect a quicker'actionthan the other in order that the roller 304 will be relieved of the tension 309 just before it commences its upward movement. During this upward movement the venous mechanismsare returned to their imtialpositions.

Pfinting mecham's'zm I angularcross-section adapte to engage the notches 318 in the lower edge of a plate 319 rigidly carried'by each of the type sectors and curved concentrically to the shaft 297. The bar is automatically swung up and registers with the notches immediately above it when the type sectors are printing position by a lever 3200f angular form, the lower end of which carries a roller 321 bearing upon the periphery of a cam 322 rigidly mounted on the shaft 8. The opposite ends of as ring 323 are connected to a portion 324 o the machine frame and a tail 325 formed integrally with a sleeve 326. This sleeveis rotatably mounted upon a stub shaft 327 and has a pair of arms 328. carrying the alignment bar between them. The hammer proper is illustrated at 329 and is carried by arms 330 and 331. A sleeve divided into end parts 332 and 333 and an inter mediate part 334 is rotatably mounted upon a shaft 335 and suchv end parts have formed integrallytherewith'the arms 330 and 331. The parts of thissleeve have interchanging shoulders 336 and 337 the latter being spaced a slight distance apart to permit of relative movement in one direction. The hammeris adapted to be actuated by a cam 338 rigidly part 334, the latter having a second lever 341 extending downwardly and resiliently connected to "an adjacent portion of the ma 342. second last mention???I chineframe by a sprin spring 343 connects sue petus and then drop clear of the latter theren by securing a'stacatto-like action. The paper which may feed which isindicated at 355 is fed from a roll 356mountedon a'shaft 357 to the printing point between the type and the ribbon 358, this ribbon passing over guides 359 and having its ends wound on spools 360 be rotated by any preferred means. I I I I adz'cating In order to indicate to the purchaser the results of each computation the machine frame isprovided with an upward extension consisting of a pair of upright sections 375 and 376 which are mounted upon the topmost bar 6 forming part of the main machine frame. These upright sections are braced by longitudinal bars 377. Journalled in these sections is a shaft 378 upon which are freely mounted a plurality of indicating wheels 379 preferably ten in number. These wheels are spaced throughout the shaft as follows: pounds, ounces, rate and price; of a 'comparatively light 'disc' having its circum-ference bent at right angles to its "main area to present a circumferential, flange 380,

'the outer surface of which represents the values computed; A hub 381- (Figs. 31 and 32) is rigidly mounted upon the shaft 378 withinthe chamber presented by each of these wheels and this hub is provided with a pair of arms 382 and 383, the free end of the arm 382 being bent at right angles to its mainglength and split to receive one of a spiral spring 384, the opposite end of this spring being connected to its adjacent wheel The free end of the other arm 383 is adapted to engage a stop 385 mounted rigidlyupo'n and extending from the flange ofthe' 'wheel.' 0n the other side of each wheel and rigidl carried thereby is a spiral controlling mem er 386 presenting'shoulders 387 with which a pawl 388 is adapted to engage for the purpose of preventing further rotation of the same.

I This pawl is carried by a. shaft 389 and is in the form of a bell crank lever, the other arm-., of' which is connected by a substantially ver- ,,tical 1ink 390 and arm 391 to therock shaft of its. respective computing mechanism." 7

- When a computing operation is taking place the downward pull; on the yoke, 280' ;mojv'es the computing pins and rockers into engagement with the respective computing Each of-these wheels consistsmembers as hereinbefore mentioned. The shafts 290 and 291 which are rocked by this action cause the pawls to move .to a predetermined extent towards the peripheries of their respective spiral members, consequently, when the wheels are rotated by means to be presently described. each will have a different extent of rotation due to position of its pawl relatively to the spiral member, the rotating action continuing only until the shoulder 387 moving in the are intersected by the upper end of the pawl engages the latter.

The means for causing rotation of the wheels consists of a drum 392 (Fig.39) containing a spiral spring 393, the ends of which timed to exert a pull on the tape and, consequently, efiect rotation ofgthe shaft 378' when the pawls have moved-intotheir controlling positions, the rotation-{of the shaft being transmitted stoeach'g'o'f "the wheels through their respectivasprin'gs '384. When the wheels have moved to-itheir' proper indicating positions eachiisalocked byan arm 399, one end oftwhich tl'is 'irigidly mounted on a shaft 400;? This-arm: is. provided with an upwardlyprojecting-lug 401 of angular form which ,is adapted toenterone of a circumferential series of openings 402 in the flange 380, such openings being located between the figures representing the values computed. The armsw399 are. swung into their locking positionsibya spring 403, one end of which is connected tozthe machine frame adjacent to shaft 8 while the other end is connected to an arm 404 having a roller 405 in bearing relation" with a cam 406, one end of the arm" being pivoted on a shaft 407 while its-OPPOSite-end is connected to the lower end of a. link 408; The upper end of this link is connected-to a comparatively short arm 409 rigidly mounted on one end of the shaft 400. The cam 406 is provided with a fall 410 and rise 411 and its main area is of substantially uniform radius [wheels The fall 410 permits the arm to "drop an extent siiflicient to exert a pull on link 408 and arm 409 thereby rotating shaft 400 and 'moving the arms 399 into their locking positions. Simultaneously with this .lockingaction the results of the computation are exposed 'to the view of the. purchaser through an aperture 415. This is effected a roller 397 bearing against a cam 398'- 'mo'unted upon the shaft 8, the cam being by a shutter 416 of substantially U form straddling the series of wheels and having its arms bearing on the shaft 378, the arms being counterweiglited at 417. An operative connec on bctween'the end arms of the locking arms 399 and the arms of the shutter are elfected by links 418. The indicating wheels are adapted to be exposed to view until the next computing operation. The cam 398 is so timed that it will cause one complete revolution of the shaft 384 for each computing operation and as the wheels will have difl'erent extents of rotation due to the position of their controlling pawls 388, each spiral spring 384 will take up the continued rotation of the shaft 378 when its respective wheel comes to a stop. W hen the wheels are released they will spring around until they resume their initial positions relatively to the shaft 378 and such shaft will then be returned to its initial position by spring 393 (Fig. 39) within drum 392 carrying the wheels with it.

Advertising mechanism.

Mounted upon a pair of hollow standards 450 and 451 and straddlingthe extension of the machine frame containing the indicating mechanism is a cylindrical casing 452 having its ends closed as at 453 and 454, such casing having a longitudinal opening 455 therein on the purchasers side. lVithin this cylindrical casing is adapted to rotate a glass tube 456 which is rigidly held between a pair of discs 457 and 458 located at opposite ends of the casing. The discs are connected by longitudinal rods 459 connected toand having their ends projecting through the discs and having nuts 460 thereon. The disc 454 is rotatably mounted upon .a hollow shaft 481 rigidly carried by the end 453, the inner end of such shaft having mounted thereon a socket 462 for an electric bulb 463, such socket being included in an electric circuit by wires464 passing through the standard 450 and connected to terminals 465 on the block 75. The other disc 458 is mounted upon a stub shaft 470 upon which is rigidly mounted a ratchet wheel 471, rotation of which is limited in one direction by a pawl 472 pivoted as at 473 to the adjacent wall 474 of the end 454, such ratchet wheel being actuated by a pawl 475 formed on the upper offset end of a pull rod 476, the lower end of which passes down through standard 451 and is connected to the yoke 280 so that with every computing operation the glass tube will be rotated a distance equal to one tooth on the ratchet wheel. The tube is adapted to carry or contain advertising matter or additional information relating to thegoods purchased.

This advertising device forms the subject.

matter of my copending divisional applica- 'tion, Serial No. 748,782,

filed November 8, 1924.

Operation.

When an article isplaced on the platform of the scale, the rack 23 is pulled downwardly thereby rotating pinion 22 and wheel 509 until the latter balances, the reading on the wheel opposite the index line (not shown, but which is disposed in alignment with the axis of pinion 22, Fig. 1) being the weight of the article. If the weight proves satisfactory to the purchaser, the rate key representing the price per pound thereof, is depressed. This action swings down the arm 224 until its notched end is in position to intersect the path of the rockers 227, 228 and 229 and through pull rod 248 and locking pawl 250 releases the price wheel representing multiples of such rate from the guide bar 170 and permits pawl 255 to lock it to the U bar. The starting key is then pressed thereby closing the switch 61 and moving gears 59 and 60 into intermeshing relation. This action sets in motion the motor 54 and, consequently, shaft 8, which shaft is responsible for the actuation of the various mechanisms. Almost immediatel with the commencement of rotation of the s aft 8 the pawl 29 moves into engagement with the teeth of the annulus 28'and locks the same against further rotation. Simultaneously the cam 216 moves out of bearing relation with the roller 215 thereby permitting the spiral spring 190 to rotate the drum 191 carrying with it the U bar, pound and ounce computing wheel and the price wheel which has been released. These wheels will be permitted to rotate until the stop 96 engages the pin 95 mounted on the annulus 28 at which point pawl 100 is swung into engagement with the teeth of the annulus 97 and the movemnt is finally stopped by the arm 106 swinging behind tail 105 of the pawl. The computing wheels have now reached their computing positions. At this point the rollers 304 and 307 carried, respectively, by the arm 273 and its assisting lever 305 have commenced to ride down the fall in each of their respective cams, and this downward movement through the various operative-connections hereinbefore described is transmitted to yoke 280, which in turn through the pull rods connected to the two series of rock shafts 290 and 291, simultaneously respectively moves the computing pins and rockers into engagement with their respective computing memhers, swings the type sectors to positions with the type at the printing point representing the weight of the article, the rate the numerals corresponding with the results to be printed by the type sectors, opposite the aperture 415, and through pull rod 476 and pawl 475 rotates the ratchet wheel 471 one tooth and, consequently, rotates the glass tube 456, bringing other advertising subject matter to view. The roller 304 is now riding along the portion 314 and'its cam so that the hammer of the printing mechanism may come into action. The type sectors are now aligned by the alignment 406 foractuating these locking devicesis so timed that such devices will be maintained in their locking positions until the commencement of the next computing operation. As soon as the type sectors are in position to print they are aligned by the alignment bar 316 which is actuated by the cam 322,

the hammer then following up by delivering a sharp blow as the roller 339 reaches the fall in the cam 338. The printing now being completed, cams 302 and 303 through arm 273 and its assisting lever 305 return i the type sector", computing rockers and computing pins to their initial positions, and as soon as the pins are clear of the peripheries of the wheels with which they have been in contact the cam 216 comes into bearing relation with its roller 215 and through the hell 1 crank lever carrying the same, shifts the rack 210 towards the rear thereby revolving the U bar 178 which moves with it the weight computing wheel and the price computing wheel which was originally released. Vhen the projections 177 on the computing wheels have come into contact with the guide bar 170, cam 243 throws out the looking bar I 234 and releases the rate lever which was depressed. This lever, as it returns to its normal position, moves back pawl 250 into position behind lug 252 thereby locking its price computing wheel in position. 1

All the mechanisms have now been returned to their initial positions with the exception of pawl 29 which'locks the annulus 28 and this pawl 'is released by the'pawl 43 reaching the fall 41 in cam 40. The gears 59-and 60 are now thrown out of 'intermeshing relation and the switch 61 opened by the striking hammer S'Z'against arm 86, such ac-' sees . opposite ends connected respectively to said tion being caused by arm 90 reaching the abrupt fall 92 in cam 91. The impact of the hammer against the arm 86 swings the main locking pawl 83 and its auxiliary pawl 701 to the rear and disengages the free nds of 7 the carrying arm 62 and lever 65 therefrom, the switch being open the machine comes to a stop thereby signalling the completion of one computing operation.

What I claim 1s 1 1. In a com uting scale, the combination with means a apted for connection to the platform thereof, of a rotary device operatively constructed and arranged to be r9- tated by said means when an article 1s placed upon the scale, said device including a pair of rotating members, both of which are rotated by the weight of an applied load, the periphery of one of said members being toothed, means for locking said toothed member, and means intermediate of said members and effecting a yielding connection therebetween for the purpose of-permitting rotation of the other. member when the toothed member is locked.

2. In a'computing scale, the combination with means adapted for connection. to the platform thereof; of a rotary device opera tively connected to the said means and constructed and arranged to be rotated when an article is placed upon the platform, said device including a shaft, a rotary indicating wheel and a rotary member having a toothed periphery mounted independently of each other upon, said shaft, means for locking said toothed member against rotation, a dis: mounted upon said shaft intermediate of said members, spiral springs located on the opposite sides of said disc and having their disc and members, stops upon said members and lateral projections upon said disc for engagement with said stops.

3. In a computing machine the combination with means adapted for connection to the platform thereof and a rotary toothed member operatively connected to the said means; of means for locking said member against rotationysaid means consistingiof a pawl movable to and from the periphery of said member, a shaft rigidly carrying said pawl, an arm upon said shaft, a cam, a second shaft, an arm carried by the second, shaft and in operative relation with said cam, a second arm carried by said second shaft and means effecting ,ayielding connection between said second arm and the arm upon. the first mentioned shaft, said means consisting of a'; nil rod divided into two parts, the ends of the partsoverlapping, and a cslpring hearing betweenthe overlapping en 3 ,0

4. In a scale,the; combinationwith [weighing means operatively controlling thecom- 'f.

r ing m nism by the weig'hlng mesa m 

